Method and apparatus for allocating terminal identifiers based on communication function

ABSTRACT

A communication means which allocates a terminal identifier to a destination communication apparatus and carries out communication with the destination communication apparatus by use of a plurality of functions including an identifier generation section 152 for generating different terminal identifiers corresponding to a function used and an identifier allocation section 114 having an identifier selecting section 104 for allocation to the destination communication apparatus. Using a plurality of different terminal identifiers (terminal function identifiers), a function to be used between the destination can be specified. Moreover, it is possible to optimize the size of a memory for storing information required for adaptive modulation control.

CROSS-REFERENCES TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.14/319,813 filed Jun. 30, 2014, which is a continuation of co-pendingU.S. patent application Ser. No. 12/282,127 filed Sep. 8, 2008, which isa National Phase of PCT/JP2007/054825 filed on Mar. 12, 2007, whichclaims priority under 35 U.S.C. § 119(a) to Patent Application No. JP2006-069486 filed in Japan on Mar. 14, 2006, all of which are herebyexpressly incorporated by reference in their entirety.

TECHNICAL FIELD

The present invention relates to optimization of information amountrequired for adaptive modulation control.

BACKGROUND OF THE INVENTION

Currently, transfer and access technologies in mobile communicationsystem are rapidly improving such as start of service of theinternational mobile telecommunication 2000 (IMT-2000). Moreover,technologies such as a high speed down-link packet access (HSDPA) arestandardized and data transfer of around 10 Mbps at maximum is expectedto be in practical use.

Meanwhile, standardization to realize broadband wireless internet accessaiming at 10 to 100 Mbps transfer rate is also being promoted andvarious techniques have been proposed.

A prerequisite for realizing wireless communication with high speedtransfer rate is raising spectrum efficiency. Because there is aproportional relation between the transfer rate and bandwidth to beused, expansion of a frequency bandwidth to be used is a simple solutionfor raising the transfer rate. However, available frequency bandwidth istight and it is unlikely that sufficient bandwidth is allocated if a newwireless communication system is constructed. Therefore, it is requiredto raise spectrum efficiency.

Moreover, another prerequisite is to provide a service in a private area(independent cell) such as wireless LAN seamlessly while realizingservice in a communication area configured by a cell such as a mobilephone.

There is a technique called one cell repeat orthogonal frequencydivision multiplexing/frequency division multiple access (hereinafterreferred to as OFDMA) which has a possibility to solve all of the above.This is a technique for carrying out communication in a communicationarea including a cell by use of the same frequency. Modulation methodthereof when communicating is OFDM, while time division multiple access(TDMA) or frequency division multiple access (FDMA) is used as an accessmethod. Needless to say, this is a communication method which enablesfaster data communication in an independent cell with a wirelessinterface commonly used with the cell area.

The OFDM and FDMA, which are elemental technology for the OFDMA, will beexplained below. The OFDM is a method used for IEEE802. 11a which is awireless system with 5 GHz band or for a digital terrestrialbroadcasting. The OFDM is a method by which several tens to thousands ofcarriers are aligned with a frequency interval, which is theoreticallyminimum to prevent interference, for simultaneous communication.Normally, the carriers are called sub-carriers in the OFDM and eachsub-carrier is digital modulated by phase shift keying (PSK), quadratureamplitude modulation (QAM), or the like to carry out communication.Further, this is regarded as a modulation method strong againstfrequency selective fading when combined with an error correctionmethod.

The FDMA is a method which accesses by dividing frequency whenreceiving/transmitting data. Normally in a communication system usingthe FDMA as an access method, frequency is divided into severalbandwidth to divide frequency bandwidth for carrying out communicationso that a terminal to be accessed is distinguished. Usually, aprotection bandwidth called a guard band is prepared between frequencybandwidths thus divided. However, in the OFDMA, the guard band is notused to prevent damages to spectrum efficiency, or if used, it is a verynarrow one with a bandwidth of some sub-carriers.

Moreover, as a method to increase communication efficiency in amulti-channel system such as the OFDMA, there is a method that causeschannel quality information (CQI) of each channel to be reported fromeach terminal to a base station, the base station allocates the bestchannel to each terminal, and the best modulation method is selectedamong them so that a user diversity effect can be obtained. This isbecause in an environment where multipath or fading exists, frequencywith better communication quality changes one right after the other andtherefore allocating a channel having good characteristics at each timeenables the terminal to obtain better communication quality than when achannel is allocated in a fixed manner.

[Patent Document 1] Published Japanese translation of a PCT applicationNo, 2002-539686

[Patent Document 2] Published Japanese translation of a POT applicationNo. 2004-510358

[Patent Document 3] Japanese Unexamined Patent Publication No.2004-179853

[Patent Document 4] Japanese Unexamined Patent Publication No.2004-253914

[Patent Document 5] Published Japanese translation of a PCT applicationNo. 2004-533792

[Patent Document 6] Japanese Unexamined Patent Publication No.2005-86818

BRIEF SUMMARY OF THE INVENTION Problem to be Solved by the Invention

In a case where the channel allocation or modulation method iscontrolled (adaptive modulation control) in response to the CQI, atransmitter side notifies selection information of functions ormodulation methods to the receiver side by inserting a flag bitindicating such information into control information and the receiverside understands how to receive information on the basis of the flag bitthus notified. However, in a cache where a flag bit is used, thereoccurs a problem that use efficiency of information is worsened if thereis deviation in utilization frequency of a specific function on thereceiver side. For example, if usage of multi-input-multi-output (MIMO)is controlled by a flag bit, even when a terminal is in motion at highspeed and is not in a condition where the terminal can use MIMO, becausea flag for controlling MIMO exists in the control information, a bitused for the flag is wasted.

Moreover, in a case where a connection is set (connection isestablished) or handover by which a base station to be connected ischanged occurs, as well as the case of channel allocation or modulationcontrolling in response to the CQI, quality of a line is measured andthe CQI may be transmitted. Even in such a case, because a flag bits areprepared on the transmitter side in response to a function indicatingselection information of functions or modulation methods, same problemoccurs.

Further, in a wireless communication system including a communicationcontrol apparatus (a base station) and a plurality of communicationterminal apparatuses (terminals), a number of a terminal temporaryidentifier for temporarily identifying a communication terminalapparatus or information amount for notifying information required fornotifying function to be used varies depending on the number ofcommunication terminal apparatuses connected to the communicationcontrolling apparatus, processing ability of the communicationcontrolling apparatus, requested communication quality, or a conditionwhere the communication terminal is set. However, because a flag bit isfixed to be used, it is difficult to flexibly use the flag bit dependingon the communication condition.

The present invention has been made in consideration of the aboveproblems and is aimed at providing a technique to optimize informationamount required for adaptive modulation control.

Means for Solving the Problem

(1) To achieve the above-mentioned purpose, a communication apparatusaccording to the present invention is a communication apparatus whichallocates a terminal identifier to a destination communication apparatusand carries out communication with the destination communicationapparatus by use of a plurality of functions and includes a identifierallocation section for generating and allocating different terminalidentifiers corresponding to functions selected from the plurality offunctions to be used for communication.

According to the communication apparatus of the present invention, itbecomes possible to identify a destination communication apparatus toidentify a function selected from the plurality of functions to be usedfor communication by use of a plurality of different terminalidentifiers (terminal function identifiers). Thus, it becomes possibleto optimize the size of a memory where information required for adaptivemodulation controlling is stored. The communication apparatus prepares aplurality of terminal identifiers for each function (for eachcombination of functions) selected from the plurality of functions to beused for communication and changes the terminal identifier depending onthe function used in communication with the destination communicationapparatus. The identifier allocation section is a constituent element torealize a function of an identifier generation section for generating agroup of terminal identifiers and a function of allocating the terminalidentifiers to the destination communication apparatus and includes afunction of an identifier selection section for selecting one terminalidentifier from a plurality of terminal identifiers.

(2) Moreover, in the communication apparatus according to the presentinvention, the terminal identifier at least includes an area whichdepends on a function.

Thus, since the terminal identifier includes at least an area whichdepends on a function, it becomes possible to specify a destinationcommunication apparatus and a function.

(3) Further, in the communication apparatus according to the presentinvention, the identifier allocation section generates and allocatesdifferent terminal identifiers corresponding to the destinationcommunication apparatus and a plurality of functions to be used forcommunication which are selected from the plurality of functions.

Thus, the identifier allocation section generates a terminal identifiercorresponding to a function. That is, a terminal identifier (a terminalfunction identifier) is generated corresponding to each function of onedestination communication apparatus. Thus, by the terminal identifier,it becomes possible to specify a destination communication apparatus anda function selected from a plurality of functions and used forcommunication. The terminal identifier includes, in addition to thefunction to identify a terminal to be a destination communicationapparatus, information for specifying a function that the destinationcommunication apparatus is to use. This is the same as adding anattribute for specifying a function to an identifier which identifies aterminal. Two information is added to a terminal identifier: whichfunction is to be used among a plurality of functions; and which item isto be used among selective items included in a function selected fromthe plurality of functions to be used for communication. Moreover, as afunction selection section selects a function to be used forcommunication from the plurality of functions as a selection function,it becomes possible to suppress the information amount required foradaptive modulation control.

(4) Further, in the communication apparatus according to the presentinvention, the identifier allocation section generates a group ofterminal identifiers corresponding to a function and allocates aterminal identifier included in the group, which corresponds to thedestination communication apparatus and to a function used, to thedestination communication apparatus.

Thus, the identifier allocation section can classify a plurality ofterminal identifiers (terminal function identifiers) for specifying adestination communication apparatus into groups and allocate a functionto each group. Thus, the terminal identifier can specify a destinationcommunication apparatus and a selective item of a function to be used.

(5) Further, in the communication apparatus according to the presentinvention, the plurality of functions include at least one of: types ofmodulation method, coding rate, stream number of MIMO (Multi Input MultiOutput) communication, number of antennas used for MIMO communication,types of automatic repeat request (ARQ), number of institutionalizedcommunication apparatuses, and notification method of the CQI (channelquality information).

Thus, enabling to select a plurality of functions which are not useddepending on the communication condition, it becomes possible tosuppress the information amount for adaptive modulation control.

(6) Further, in the communication apparatus according to the presentinvention, a function selecting section for selecting a predeterminednumber of functions to be used for communication is further included andthe identifier allocation section generates and allocates a terminalidentifier to the destination communication apparatus on the basis ofthe selected function.

Thus, the function selecting section can select a selection function onthe basis of communication condition. Therefore, it becomes possible tomore appropriately select the selection function and to optimize theinformation amount required for adaptive modulation control.

(7) Further, in the communication apparatus according to the presentinvention, the function selecting section limits the number of functionsto be used on the basis of at least one of: number of destinationcommunication apparatuses to be connected, requested communicationquality, and information received from the destination communicationapparatus.

Thus, the function selecting section can limit the number of functionsto be selected depending on the processing ability of the destinationcommunication apparatus on the basis of at least one of: number ofdestination communication apparatuses to be connected, requestedcommunication quality, and information received from the destinationcommunication apparatus. Therefore, it becomes possible to moreappropriately select the selection functions and to optimize theinformation amount required for adaptive modulation control.

(8) In the communication apparatus according to the present invention,the function selecting section selects a function to be used on thebasis of at least one of: the number of destination communicationapparatuses to be connected, requested communication quality, andinformation received from the destination communication apparatus.

Thus, the function selecting part can change the functions to beselected depending on the processing ability of the destinationcommunication apparatus on the basis of at least one of: number ofdestination communication apparatuses to be connected, requestedcommunication quality, and information received from the destinationcommunication apparatus. Therefore, it becomes possible to select aselective function depending on the communication condition.

(9) Further, a communication apparatus according to the presentinvention is a communication apparatus which allocates a terminalidentifier to a destination communication apparatus and carries outcommunication with the destination communication apparatus by utilizinga plurality of functions, wherein the terminal identifier includes atleast an area which depends on the function, wherein the area whichdepends on the function includes an identifier allocation section forgenerating different terminal identifiers corresponding to a pluralityof functions selected from the plurality of functions and used forcommunication and for allocating the identifiers to the destinationcommunication apparatus.

Thus, since the terminal identifier includes an area (mode number) whichdepends on a function, it becomes possible to specify a destinationcommunication apparatus and a function.

(10) Moreover, in the communication apparatus according to the presentinvention, the terminal identifier includes a terminal temporaryidentifier which temporarily identifies a terminal while the area whichdepends on the function includes mode numbers corresponding to each of aplurality of combinations of a plurality of functions.

According to this configuration, it becomes possible to efficiently usea memory for a terminal function identifier which is a combination of aterminal temporary identifier and a mode number depending on thecondition of the communication apparatus. Moreover, it becomes possibleto optimize utilization condition of a memory depending on the conditionof the communication apparatus. Further, it becomes possible to reducethe amount of memory allocated to a terminal function identifier becauseutilization condition of the memory can be changed depending on thecondition of the communication apparatus.

(11) Further, in the communication apparatus according to the presentinvention, the identifier allocation section determines the size of areawhich depends on the function on the basis of at least one of: number ofdestination communication apparatuses to be connected, requestedcommunication quality, and information received from the destinationcommunication apparatus.

Thus, the identifier allocation part can flexibly change the size of thearea which depends on the function depending on the communicationcondition. Therefore, it becomes possible to use a memory depending onthe communication condition and to optimize information amount requiredfor adaptive modulation control. Moreover, since allocation of memorycan be changed depending on the communication condition, it becomespossible to suppress memory amount as a whole.

(12) In the communication apparatus according to the present invention,the identifier allocation section further includes a transmissionsection for generating function corresponding information correspondingfunctions correlated with a plurality of terminal identifiers thusgenerated and the terminal identifiers and for transmitting the functioncorresponding information thus generated to a destination communicationapparatus.

Thus, by notifying the function corresponding information to thedestination communication apparatus, the destination communicationapparatus can obtain information specifying a function added to theterminal identifier (terminal function identifier). The identifierallocation section transmits the function corresponding information thusgenerated to the destination communication apparatus through thetransmission section for notification to the destination communicationapparatus.

(13) A communication method according to the present invention is acommunication method to allocate a terminal identifier to a destinationcommunication apparatus and to carry out communication with thedestination communication apparatus by use of a plurality of functions,wherein different terminal identifiers are generated for each offunction used and are allocated to the destination communicationapparatus.

According to the communication method of the present invention, itbecomes possible to specify a destination communication apparatus and afunction to be used by use of a plurality of different terminalidentifiers (terminal function identifiers). Thus, it becomes possibleto optimize the size of a memory where information required for adaptivemodulation controlling is stored.

Advantageous Effect of the Invention

According to the present invention, it becomes possible to optimize theinformation amount required for adaptive modulation control.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 A block diagram showing a configuration example of acommunication control apparatus of a first embodiment.

FIG. 2 A block diagram showing a configuration example of acommunication terminal apparatus of a first embodiment.

FIG. 3 A block diagram showing an example of configuration regardinggeneration of a terminal function identifier and an identifierallocation section among functions of a communication control section ofthe first embodiment.

FIG. 4 A block diagram showing a configuration example of an identifierselecting section of the first embodiment.

FIG. 5 A block diagram showing a configuration example of a conventionallogical identifier selecting section.

FIG. 6 A view showing an example of a frame used for an OFDMA system.

FIG. 7 A view showing an example of a function for allocation to aterminal function identifier in the first embodiment.

FIG. 8 A view showing an example of partially selecting a function foruse.

FIG. 9 Another view showing an example of partially selecting a functionfor use.

FIG. 10 A view showing an example of a case where a combination ofselective items of functions are allocated to a terminal functionidentifier.

FIG. 11 A sequence diagram showing an example of a flow of processingbetween the communication control apparatus and a communication terminalapparatus.

FIG. 12 A view showing an example of packet configuration fortransmission to the communication terminal apparatus in a conventionalmethod and the first embodiment.

FIG. 13 A view showing an example of packet configuration fortransmission to the communication terminal apparatus in a conventionalmethod and a second embodiment.

FIG. 14 A block diagram showing a configuration example of acommunication control apparatus of a third embodiment.

FIG. 15 A block diagram showing a configuration example of acommunication terminal apparatus of the third embodiment.

FIG. 16 A view showing an example of a function controlled by thecommunication control apparatus in the third embodiment.

FIG. 17 A view showing an example of a utilization condition of a memoryin a function prioritized condition.

FIG. 18 A view showing an example of a utilization condition of a memoryin a function limited condition.

FIG. 19 A view showing an example of a utilization condition of a memoryin a terminal number prioritized condition.

FIG. 20 A view showing an example of utilization ratio of a memory for aterminal function identifier.

FIG. 21 A view showing an example of allocation of a mode number in thecase of function limited condition shown in FIG. 18.

FIG. 22 A view showing an example of a frame configuration and anexample of data configuration of a function map.

DESCRIPTION OF THE REFERENCE NUMERALS

-   -   100,300: Communication control apparatus;    -   101,301: Communication control section;    -   102: Terminal ID selecting section;    -   103: Modulation method selecting section;    -   104,304: Identifier selecting section;    -   105: Control slot generation section;    -   106: Data slot generation section;    -   107: Frame data generation section;    -   108: AQR control section;    -   109: Mapping section;    -   110: Modulation section;    -   111: RF section;    -   112: Uplink receiving section (receiver);    -   113: Transmission section;    -   114,305: Identifier allocation section;    -   151,302: Function selecting section;    -   152,303: Identifier generation section;    -   153: Function corresponding information management section;    -   161: First selecting section;    -   162: Second selecting section;    -   163: Logical identifier selection section;    -   200,400: Communication terminal apparatus;    -   201,401: Communication control section;    -   202: RF section;    -   203: Control slot demodulating section;    -   204: Data slot demodulating section;    -   205: CQI measuring section;    -   206: ARQ control section; and    -   207: Uplink transmission section

DETAILED DESCRIPTION OF THE INVENTION Best Mode for Carrying Out theInvention

Next, embodiments of the present invention will be explained withreference to figures. Same reference numeral is denoted to a constituentelement having same configuration or a function or to apart equivalentthereto and explanation thereof is omitted.

The present invention can be applied to a wireless communication systemincluding a communication apparatus for transmitting data by adaptivemodulation, a communication apparatus for receiving adaptive modulationdata, and to a communication apparatus included in a wirelesscommunication system. In the explanation below, it is assumed that acommunication apparatus which controls adaptive modulation and transmitsdata is a communication control apparatus and a communication apparatuswhich receives adaptive modulation controlled data is a communicationterminal apparatus for easy of explanation. However, the presentinvention can be applied to a communication apparatus which usesadaptive modulation control communication method and carries outcommunication with a communication apparatus on a destination side(destination communication apparatus) by use of a plurality of functionshaving a plurality of selective items. Moreover, a communicationterminal apparatus may be referred to as a “terminal”.

In the present application, following terms are used for explanation.The adaptive modulation control is a notion which is executed in a casewhere channel allocation or modulation method is controlled in responseto CQI, a case where the communication controlling apparatus establishesconnection upon start of communication with a communication terminalapparatus, a case of handover where a communication terminal apparatuschanges a communication controlling apparatus (base station), and thelike.

It is a prerequisite that a communication apparatus selects at least onefrom a plurality of functions having a plurality of selective items anduses one selective item of the selected function to carry outcommunication with a destination communication apparatus. The pluralityof functions include at least one of: types of modulation method, codingrate, stream number of MIMO communication, number of antennas used forMIMO communication, types of automatic repeat request (ARQ), number ofinstitutionalized communication apparatuses, and notification method ofthe CQI.

A terminal unique identifier is a unique identifier of a terminal and isalso referred to as a physical identifier. The terminal temporaryidentifier is an identifier temporarily allocated to a terminal and alsoreferred to as a logical identifier. It is an identifier added by theterminal controlling apparatus and is added to the terminal every timethe communication terminal apparatus establishes connection with thecommunication control apparatus.

A terminal function identifier is a temporary identifier for correlatinga destination communication apparatus and a function used forcommunication and is generated by the communication control apparatus.Moreover, in the present application, a terminal identifier is a widenotion including a terminal unique identifier, a terminal functionidentifier, and other identifiers for identifying a destinationcommunication apparatus.

Further, in the following explanation will be given using downlink inthe OFDMA system (communication from a base station to a mobilestation). However, the present invention can be applied to a case ofuplink.

First Embodiment

In a first embodiment, a case will be explained where a terminalfunction identifier to which attribute of a function to be used incommunication between a communication control apparatus and acommunication terminal apparatus is added is used as a terminaltemporary identifier.

FIG. 1 is a block diagram showing a configuration example of acommunication control apparatus 100 of the first embodiment.

A communication control section 101 is in charge of information datathrough a backbone handled by the communication control apparatus 100 orcontrol of each block of the communication control apparatus 100.Moreover, the communication control section 101 generates a plurality ofterminal function identifiers and includes a function correspondinginformation for specifying correspondence between the plurality ofterminal function identifiers and functions. This will be explainedlater using FIG. 3.

A terminal ID selecting section 102 is instructed a destinationcommunication apparatus (communication terminal apparatus) to which theterminal ID selecting section 102 is to transmit data by thecommunication control section 101 and outputs a terminal uniqueidentifier of the communication terminal apparatus as terminal IDinformation. The terminal ID selecting section 102 may output a terminalfunction identifier instead of the terminal unique identifier as theterminal ID information. This is enabled in a case where a terminalfunction identifier is already allocated to a communication terminalapparatus on the communication destination side and the communicationcontrol section 101 acquires the terminal function identifier.

A modulation method selecting section 103 selects a modulation methodincluding a modulation method, an coding method, ON/OFF of soft handovercontrol, and MIMO, and outputs the modulation method thus selected asmodulation method information according to an instruction from thecommunication control section 101.

An identifier selecting section 104 selects one from a plurality ofselective items of a selection function according to an instruction fromthe communication control section 101 and selects a terminal functionidentifier correlated with the selected selective item. Specifically, onthe basis of terminal ID information (a terminal unique identifier orterminal function identifier), a modulation method information, ARQcontrol information indicating a type of selected ARQ, or the like ofthe communication terminal apparatus to be a destination, a terminalfunction identifier corresponding to a selective item of a function tobe used is selected from a plurality of terminal function identifiers.Details will be described later using FIG. 4.

A control slot generation section 105 generates control slot data fromthe selected terminal function identifier and modulation method. A dataslot generation section 106 processes information data according to aninstruction from the communication control section so that the data hasappropriate length and adds an ARQ control signals and an errordetection signal.

A frame data generation section 107 assembles a frame from the controlslot data thus generated and data of data slot. An ARQ control section108 carries out control of ARQ by signals from the communication controlsection 101 and an uplink receiving section 112. Control result isoutputted as ARQ control information.

A mapping section 109 determines which data is to be allocated to eachsub-carrier according to a generated packet and selected modulationmethod. A modulation section 110 carries out modulation processing onthe basis of mapping result of data and modulation method.

An RF section 111 converts modulation signal into transmission frequencyfrom an antenna, amplifies to required transmission power, and transmitsconverted modulation signal. The RF section 111 includes a plurality ofantennas. The uplink receiving section (receiver) 112 receives an uplinksignal from the communication terminal apparatus. A transmission section113 includes a function to transmit data to the destinationcommunication apparatus and includes the modulation section 110 and theRF section 111 in FIG. 1.

FIG. 2 is a block diagram showing a configuration example of acommunication terminal apparatus 200 of the first embodiment. Acommunication control section 201 is in charge of communication controlin the communication terminal apparatus 200. Moreover, the communicationcontrol section 201 judges attribute of a function added to a terminalfunction identifier and understands what type of adaptive modulationcontrol is carried out on the communication control apparatus 100 side.

An RF section 202 takes a necessary signal from received signals andconverts the signal into a baseband signal. A control slot demodulatingsection 203 demodulates a control slot. A data slot demodulating section204 demodulates following data slot on the basis of demodulation resultof the control slot.

A CQI measuring section 205 generates quality information of eachsub-channel, CQI, and the like from a received signal. An ARQ controlsection 206 judges which slot can be received and which slot cannot bereceived from the demodulated data slot and generates an ARQ controlsignals to be transmitted to the communication control apparatus 100. Anuplink transmission section 207 transmits data to the communicationcontrol apparatus 100.

FIG. 3 is a block diagram showing an example of configuration regardinggeneration of a terminal function identifier and an identifierallocation section 114 among functions of the communication controlsection 101 of the communication control apparatus 100 of the presentembodiment. Moreover, the communication control section 101 includes afunction selecting section 151, an identifier generation section 152,and a function corresponding information management section 153 asconstituent elements regarding generation of a terminal functionidentifier. Further, an identifier allocation section 114 has a functionto generate different terminal identifiers (terminal functionidentifiers) for functions used and to allocate the identifiers to thedestination communication apparatus. In FIG. 3, an example which isrealized by the identifier generation section 152 and the identifierselection section 104 (including the identifier generation section 152and the identifier selection section 104) is shown.

The function selecting section 151 inputs designated functioninformation notified by the communication terminal apparatus 200,selects at least one function from a plurality of functions on the basisof inputted designated function information, processing ability of thecommunication control apparatus 100, and communication condition(traffic condition, quality of a propagation channel, requestedcommunication quality, and the like) to determine a selection function,and outputs the selection function thus determined as selection functioninformation. The designated function information is informationgenerated by the communication control section 201 of the communicationterminal apparatus 200 and designates a function in a case where theselective items that a plurality of functions have is changeable and afunction when a fixed value is used. Moreover, the function selectingsection 151 can select an appropriate function as a selective functionon the basis of other factors such as communication condition or abilityof the communication control apparatus 100 even if the function isdesignated by the designated function information. Further, the functionselecting section 151 can adjust the number of functions selected asselection functions. Generated selection function information isoutputted to the identifier generation section 152.

Here in FIG. 3, a case where designated function information is notifiedfrom the communication terminal apparatus 200 is shown. However,selection function may be selected in the communication controlapparatus 100 without notice of the designated function information fromthe communication terminal apparatus 200.

The identifier generation section 152 generates a plurality of differentterminal function identifiers. Specifically, the identifier generationsection 152 generates terminal function identifiers on the basis ofselection function information selected by the function selectingsection 151. Specifically, the identifier generation section 152generates a plurality of terminal function identifiers specifying eachof a plurality of selection functions that the selective function hasfor each of the communication terminal apparatus 200. In a case wherethere are a plurality of selection functions, a plurality of terminalfunction identifiers which specify combinations of a plurality ofselective items that each of the plurality of selective functions hasare generated. Moreover, the identifier generation section 152 generatesfunction corresponding information which corresponds the selective itemscorrelated with each of a plurality of generated terminal functionidentifiers and the terminal function identifiers. Specific examples ofthe terminal function identifier and the function correspondinginformation will be described later using FIG. 10. The identifiergeneration section 152 generates function corresponding information foreach of communication terminal apparatuses 200 to be connected. Thefunction corresponding information thus generated is outputted to thefunction corresponding information management section 153.

The function corresponding information management section 153 includes asaving area for saving function corresponding information generated bythe identifier generation section 152, stores the function correspondinginformation in the saving area, and manages it. Moreover, the functioncorresponding information management section 153 receives notificationof a terminal function identifier and outputs function correspondinginformation of the notified terminal function identifier.

Next, the identifier selecting section 104 will be explained. FIG. 4 isblock diagram showing a configuration example of an identifier selectingsection of the present embodiment. The identifier selecting section 104includes a first selecting section 161 and a second selecting section162. The first selecting section 161 inputs terminal ID information fromthe terminal ID selecting section 102 and inputs terminal-terminalfunction identifier information from the communication control section101. The terminal-terminal function identifier information corresponds aterminal unique identifier and a plurality of terminal functionidentifiers, In the present embodiment, because a plurality of terminalfunction identifiers are allocated to one communication terminalapparatus 200, a plurality of terminal function identifiers correspondto a terminal unique identifier. The first selecting section 161 selectsa plurality of terminal function identifiers allocated to thecommunication terminal apparatus 200 on the basis of the terminal IDinformation and the terminal-terminal function identifier. In a casewhere one of the terminal function identifiers is notified as theterminal ID information, the first selecting section 161 searches for aterminal unique identifier corresponding to the notified terminalfunction identifier and selects a plurality of terminal functionidentifiers (terminal function identifier group) corresponding to thesearched terminal unique identifier. The selected terminal functionidentifier group is outputted to the second selecting section 162.

The second selecting section 162 selects one terminal functionidentifier from the terminal function identifier group notified from thefirst selecting section 161 on the basis of modulation methodinformation notified from the modulation method selecting section 103,ARQ control information notified from the ARQ control section 108, andfunction controlling information notified from the communication controlsection 101. The function control information is information generatedby the communication control section 101 for controlling a function tobe used on the basis of receiving quality information or the likenotified by the communication terminal apparatus 200 and specifies whichselective item of a plurality of selective items that the function hasis to be used. The function control information includes, for example,control information such as ON/OFF of soft handover.

Here, a difference from a conventional method will be explained. FIG. 5is a block diagram showing a configuration example of a conventionallogical identifier selection section 163. Conventionally, thecommunication terminal apparatus 200 and a terminal temporary identifier(logical identifier) are in one-to-one relation and therefore a logicalidentifier is determined on the basis of a terminal unique identifierand terminal-logical identifier corresponding information.

Here in FIG. 4, an example where the identifier selection section 104includes two selection sections for selecting a terminal functionidentifier is shown. However, this is a configuration shown for easy ofcomparison with the conventional example of FIG. 5 and the identifierselection section 104 may include one selection section and all theinformation may be inputted at a time to determine a terminal functionidentifier. The identifier selection section 104 may be provided in thecommunication control section 101 or may be a part of function executedby the communication control section 101. Further, each constituentelement provided in the communication control section 101 shown in FIG.3 may be provided in other locations and may not be limited within thecommunication control section 101.

Next, form of data transmitted and received between the communicationcontrol apparatus 100 and the communication terminal apparatus will beexplained. FIG. 6 is a view showing an example of a frame used for anOFDMA system. A frame 500 includes a plurality of slots 502 determinedby a predetermined time length and a predetermined frequency bandwidth.The OFDMA is an FDMA system utilizing an OFDM and carries out managementof resources by the section of a sub-channel 501, which is a dividedsub-carrier in a predetermined frequency bandwidth. Depending on thecondition, management is carried out by the section of a slot 502 whichis generated by further dividing the sub-channel 501 in time direction.In the present embodiment, an example where the slot 502 is a minimumsection for management of resources will be explained. Moreover, tocarry out management of the slot 502, management will be carried out bythe section of the frame 500 with a fixed length that includes apredetermined number of slots 502. At the top of the frame 500,allocation information of following slot group 502 and a control slot503 for control of storing modulation methods of each of slots 502 areprovided, followed by slots 502 for data. The control slot 503 is anarea with its usage previously determined for control information in theframe 500. The control slot 503 is transmitted by a predeterminedmodulation method, for example, binary phase shift keying (BPSK) whichcan ensure the reliability most, and following slots 502 for data aretransmitted by the modulation method that follows the content of thecontrol slot 503.

As a policy applied when allocating slots 502 for data to each ofcommunication terminal apparatuses 200, a method called “localized”which allocates a slot 502 to a communication terminal apparatus 200 insub-channel direction, that is, time axis (a method to allocate acheckered area 504) or a method called “distributed” which allocates aslot 502 in frequency axis (a method to allocate shadowed area 505) isused. Localized utilizes CQI reported by a communication terminalapparatus 200 and enables to increase user diversity gain by allocatinga sub-channel having good characteristics for the communication terminalapparatus 200 to a slot, while the distributed enables to obtainfrequency diversity effect by the allocated slot.

Which allocation policy is to be used is not directly related to thepresent invention. However, as an example, the localized may be usedwhen moving speed of the communication terminal apparatus 200 (mobileterminal) is not so fast and accuracy of the CQI can be sufficientlyensured, while the distributed may be used when moving speed of thecommunication terminal apparatus 200 is fast and accuracy of the CQIcannot be sufficiently ensured. Moreover, it is conceivable that thedistributed may be used for a communication terminal apparatus 200having extremely low transmission frequency and low needs to report theCQI such as a remote sensor.

In the present embodiment, the area 505 of the distributed is furtherdivided in time axis so that information amount for each slot becomesthe same as the case of the localized. In the present embodiment, alocalized slot is divided into eight in frequency axis. Therefore, adistributed slot is also divided into eight in time axis. A referencenumeral 508 indicates length of one slot in time axis and the lengthindicated by the reference numeral 508 is divided into eight.

Next, function used between the communication control apparatus 100 andthe communication terminal apparatus 200 and a procedure for allocatingthe function to a terminal function identifier will be explained. In thecommunication between the communication control apparatus 100 and thecommunication terminal apparatus 200, a plurality of functions are usedand each of the plurality of functions has a plurality of selectiveitems. One selective item is selected for use for each of the pluralityof functions. Therefore, if one function is selected for use, thecommunication control apparatus 100 selects one from a plurality ofselective items of the selected function. Moreover, if a plurality offunctions are used, the communication control apparatus 100 selects onefrom the combined number of selected items of the selected functions.

FIG. 7 is a view showing an example of a function for allocation to aterminal function identifier. Each of the functions shown in FIG. 7 hasselective items for selecting a type of the function. In the presentembodiment, a case where four functions are used is taken as an exampleand in FIG. 7, each function is shown by using Flags 1 to 4. In FIG. 7,an example where function of Flag 3 has four selective items and otherfunctions in other Flags have two selective items is shown. The exampleshows a case where Flag 3 requires a 2-bit flag bit and the other Flagsrequire 1-bit flag bit to transfer selective items (information) of afunction to be used. Therefore, in the present embodiment, the fourfunctions are allocated to a terminal function identifier (attributes ofthe four functions are added to a terminal temporary identifier).

Each of the functions indicates the following: First function is forswitching localized/distributed shown in Flag 1; Second function is forswitching ON/OFF of soft handover in Flag 2; Third function is for thenumber of transmission antennas of MIMO shown in Flag 3; and Fourthfunction is for switching long/short of timeout period of ARQ shown inFlag 4. Because each function does not have a relation with the essenceof the present invention, explanation will be given briefly.

Regarding the localized and distributed, explanation has been given inFIG. 6. Soft handover is a technique to prevent temporary disconnectionin handover where a connection host moves from cell or a sector toanother cell or a sector by connecting with both cells or sectors at aborder and to prevent unstable communication at the border. Although itdiffers depending on the method, to realize soft handover, it isrequired to operate at least a plurality of functions on the receiverside. Therefore, it may cause increase in circuit size or powerconsumption.

MIMO uses a plurality of antennas on both the transmitter and receiversides: a transmitter transmits a plurality of signals from differentantennas simultaneously; and a receiver receives the signals by use ofthe plurality of antennas and separates each of transmission signalsfrom the received signals by signal processing. Therefore, depending onthe condition of a propagation channel between transmitter and receiversides, number of signals which can be separated differs.

Time out period of ARQ is related to real time property of information.If the time out period is set long, reliability of information rises butreal time property is lowered. If the time out period is set short,reliability of information is lowered but real time property rises.

To control all of these functions during communication, 5-bitinformation is required. However, not all the communication terminalapparatuses 200 need to switch these functions. FIGS. 8 and 9 show anexample where part of functions are selected and used. For example, acommunication terminal apparatus 200 which moves at a high speed doesnot use MIMO and depending on the moving speed, it is preferable thatthe apparatus uses only the distributed. In such a case, as shown inFIG. 8, it is sufficient that information of Flags 2 and 4 are notifiedto the communication terminal apparatus 200 and information of Flags 1and 3 do not need to be notified. Moreover, in a low bit-ratecommunication such as an ordinary verbal communication, MIMO is not usedand the ARQ timeout period is set to “short” and not switched. In thiscase, as shown in FIG. 9, information of Flags 1 and 2 may be notifiedto the communication terminal apparatus 200. Further, though not shownin the figures, there may be a case where a communication terminalapparatus 200 used as a remote sensor (mobile terminal) does notactually move. In such a case, distributed, no soft handover, no MIMO,and “long” as ARQ timeout period are set and the parameters are notchanged during communication. As described above, in such cases, 5-bitinformation amount for function selection is not efficiently used. Thepresent invention is for solving this problem.

In the present embodiment, a terminal function identifier of acommunication terminal apparatus 200 which can be dynamically attachedis used for selection of these functions and for distinction instead ofthe flag bit and notification to the communication terminal apparatus200 is made. The terminal temporary identifier (logical identifier) ofthe communication terminal apparatus 200 is an ID (identifier) allocatedtemporarily when the communication terminal apparatus 200 is connectedwith the communication control apparatus 100 and is used for reductionof information amount when the bit length of the terminal uniqueidentifier (physical identifier) uniquely allocated to the communicationterminal apparatus 200 is long. Generally, one terminal temporaryidentifier is allocated to one communication terminal apparatus 200 andat most, a few multicast addresses are allocated. In the presentembodiment, a terminal function identifier which correlates the terminaltemporary identifier with the function is generated and the terminalfunction identifiers for the number of combination of functions used bythe communication terminal apparatus 200 (number of combination ofselective items each function has) are allocated.

Allocation of a terminal function identifier will be explained by use ofFIG. 10. FIG. 10 is a view showing an example of a case where acombination of selective items of functions are allocated to a terminalfunction identifier. Here, a case where functions shown in FIG. 9 areselected among functions shown in FIG. 7 is taken as an example forexplanation. In FIG. 10, a case where only switchinglocalized/distributed and switching in soft handover are used and fixedvalues are used for other functions is shown. To allow these twofunctions to be switched, there are four patterns of combination asshown in FIG. 10 and a terminal function identifier is allocated to eachof the combination. As shown in FIG. 10, the allocated terminal functionidentifier may not be continuous values. As described above, the exampleshown in FIG. 10 is a case where two functions are selected, there arefour patterns of combination of selective items of the selected twofunctions, and four terminal function identifiers are generated. FIG. 10shows function corresponding information that specifies functioncorresponding to four terminal function identifiers.

Next, an example of a procedure for allocating functions and a terminalfunction identifier to the communication terminal apparatus 200 will beshown. FIG. 11 is a sequence diagram showing an example of a flow ofprocessing between the communication controlling apparatus 100 and thecommunication terminal apparatus 200. First, the communication terminalapparatus 200 carries out connection request to the communicationcontrol apparatus 100 (S11). At this time in the communication terminalapparatus 200, the communication control section 201 generates afunction to enable switching of function depending on the communicationcondition by allowing switching and a function to use a fixed valuewithout switching a function as designated function information and thecommunication terminal apparatus 200 notifies the designated functioninformation as current terminal ability to the communication controlapparatus 100.

The communication control apparatus 100 receives the connection requestand transmits connection permit to the communication terminal apparatus200 which made the connection request (S12). At this time in thecommunication control apparatus 100, the function selecting section 151of the communication control section 101 determines a predeterminednumber of functions from the plurality of functions on the basis of thedesignated function information notified by the communication terminalapparatus 200 and control information notified by the communicationterminal apparatus 200 (information notified by the control slot in FIG.6). The identifier generation section 152 generates a terminal functionidentifier and function corresponding information on the basis ofselection function selected by the function selecting section 151 andthe communication control apparatus 100 notifies the terminal functionidentifier group and the function corresponding information (combinationof functions) thus generated to the communication terminal 200.

The communication terminal apparatus 200 receives the connection permit,terminal function identifier group, and function correspondinginformation from the communication control apparatus 100 and repliesconnection confirmation (S13). The communication control apparatus 100and the communication terminal apparatus 200 use the allocated terminalfunction identifier (terminal function identifier group) in thecommunication thereafter (S14). The identifier selecting section 104 ofthe communication control apparatus 100 selects one terminal functionidentifier from the terminal function identifier group thus generatedand carries out communication. This lasts until there is change in thefunction corresponding information. That is, this lasts until thecommunication terminal apparatus 200 selects again a function whichenables switching of functions and notifies the designated functioninformation to the communication control apparatus 100 or thecommunication control apparatus 100 changes a function in response tothe change in communication condition and there occurs a change.

In a case where there is a change in a parameter, which enables afunction to be changeable, by increased moving speed or the like of thecommunication terminal apparatus 200, the communication terminalapparatus 200 notifies a terminal ability change request to thecommunication control apparatus 100 (S15). At this time in thecommunication terminal apparatus 200, the communication control section201 generates again a function to enable switching of function dependingon the communication condition by allowing switching and a function touse a fixed value without switching a function as designated functioninformation and the communication terminal apparatus 200 notifies againthe designated function information thus generated as current terminalability to the communication control apparatus 100.

The communication control apparatus 100 receives the terminal abilitychange request and notifies the communication terminal apparatus 200which notifies the terminal ability change request an ability changepermit (S16). Moreover, in the communication control apparatus 100, thefunction selecting section 151 of the communication control section 101generates the terminal function identifier (terminal function identifiergroup) and the function corresponding information again and thecommunication control apparatus 100 notifies the terminal functionidentifier group and the function corresponding information. Theterminal function identifier group generated again at this time mayoverlap the former one.

The communication terminal apparatus 200 receives the ability changepermit, terminal function identifier group, and function correspondinginformation from the communication control apparatus 100 and transmitsability change confirmation to the communication control apparatus 100(S17). The communication control apparatus 100 and the communicationterminal apparatus 200 use the re-generated terminal function identifiergroup in the communication thereafter (S18).

Moreover, in the communication control apparatus 100 and thecommunication terminal apparatus 200, following operations are carriedout in addition to the operation shown in FIG. 11.

First, an explanation will be given of a case of the communicationcontrol apparatus 100. The communication control section 101 utilizesinformation data from the backbone or other control data such as the CQIdata transmitted from the communication terminal apparatus 200 todetermine which data slot is to be allocated to which communicationterminal apparatus 200 and to generate allocation information and at thesame time determines modulation methods of each data slot, Selectionbetween distributed and localized is also made here, The allocationinformation and the modulation information are inputted to the terminalID selecting section 102, the modulation method selecting section 103,and the identifier selecting section 104.

The control slot generation section 105 inputs the terminal functionidentifier and the modulation method and generates data for a controlslot according to the acquired terminal function identifier andmodulation method. The communication control section 101 transmits datafor the communication terminal apparatus 200 to the data slot generationsection 106 and the data slot generation section 106 generates contentof the data slot The frame data generation section 107 aligns data forthe data slot on the basis of the allocation information and themodulation information to complete frame data. The frame data thuscompleted is transmitted to the communication terminal apparatus 200through the mapping section 109, the modulation section 110, and the RFsection 111.

Form of an uplink signal transmitted from the communication terminalapparatus 200 can be basically any form as long as the signal can ensurereliability that enables to carry out each of processing shown in FIG.11 or ARQ control. For example, a method used for personal digitalcellular (PDC) or a method used for wireless local area network (LAN)may be used.

The ARQ control section 108 carries out control of ARQ by controlsignals transmitted from the communication terminal apparatus 200 to thedata of the transmitted slot. Because the communication terminalapparatus 200 transmits transmission/non-transmission of data of theslot on the basis of the ARQ control signals at the time oftransmission, content of each slot is transmitted again by the signals.In a case where transmission fails after trying retransmission for apredetermined period of time, the transmission data is discarded astimeout. The timeout period is set by information exchanged when thecommunication terminal apparatus 200 makes a connection request andinformation exchanged when the ability change is made.

When the soft handover is carried out, the communication control section101 carries out communication through a communication control sectionand a backbone of a soft handover target and the soft handover isrealized by transmission from both sides after adjusting timing,modulation method, and transmission data to be transmitted from bothsides. Whether this soft handover is carried out or not is set byinformation exchanged when the communication terminal apparatus 200makes connection and information exchanged at the time of abilitychange.

Next, the communication terminal apparatus 200 will be explained. Thecommunication terminal apparatus 200 carries out a connection requestfollowing procedures shown in FIG. 11 upon finding the communicationcontrol apparatus 100. At this time, the communication control section201 receives a control slot transmitted from the communication controlapparatus 100 in advance to check the quality of the received signal,determines which function is used with a fixed value and which functionis selective, and notifies them by use of designated functioninformation to the communication control apparatus 100 at the time ofconnection request. The communication control apparatus 100 whichreceived the connection request determines a terminal functionidentifier group to be used by the communication terminal apparatus 200and notifies the determination to the communication terminal apparatus200 which made the connection request. However, at this point, thecommunication terminal apparatus 200 itself does not know which terminalfunction identifier is allocated and therefore, the communicationcontrol apparatus 100 notifies this information by use of an identifierfor broadcasting. The identifier for broadcasting indicates that theinformation must be received by all the communication terminalapparatuses 200 included in the network and a previously fixed value isto be used. The communication terminal apparatus 200 carries outcommunication using a terminal function identifier if the terminalfunction identifier information of the communication terminal apparatus200 itself is included in the broadcast information. If allocationinformation of the terminal function identifier could not be received,connection request is made again.

Next, a case where a terminal function identifier of the presentembodiment is used and a case where a conventional terminal temporaryidentifier and a flag bit are used will be compared. FIG. 12 is a viewshowing an example of packet configuration for transmission to thecommunication terminal apparatus 200 in a conventional method and thefirst embodiment. The upper part of FIG. 12 is an example ofconventional packet configuration while the lower part of FIG. 12 is anexample of packet configuration of the present embodiment.

A header part 1201 includes control information other than a flag bitsuch as an ID for identifying the communication control apparatus 100 ora time stamp. A terminal temporary identifier part 1202 stores aterminal temporary identifier (logical identifier). A flag bit part 1203stores a flag bit. A pay load part 1204 stores communication data mainbody. The terminal temporary identifier part 1202 is a logicalidentifier used by a conventional method and has a one-to-one relationbetween the communication control apparatus 100 where the terminaltemporary identifier part 1202 is stored and the communication terminalapparatus 200.

Moreover, a terminal function identifier part 1205 stores the terminalfunction identifier explained in the present embodiment. The terminaltemporary identifier part 1202 and the flag bit part 1203 are equivalentto the terminal function identifier part 1205. One or a plurality ofterminal function identifiers are allocated to one communicationterminal apparatus 200 and at the same time functions used to eachterminal function identifiers are allocated. Therefore, an ability tospecify a communication terminal apparatus 200 and an ability to specifya function to be used when communicating are correlated.

As shown in FIG. 12, the terminal function identifier part 1205 selectsa function depending on the communication condition and therefore anarea of the flag bit part 1203 is reduced and information amount isreduces as a whole. Moreover, in FIG. 12, an example where informationamount of the terminal function identifier part 1205 becomes larger thanthe information amount of the terminal temporary identifier part 1202 isshown. However, there may be a case where the terminal functionidentifier part 1205 has the same information amount as the terminaltemporary identifier part 1202. In FIG. 12, the terminal functionidentifier part 1205 issues a plurality of identifiers to onecommunication terminal apparatus 200 and therefore a case where theinformation amount of the terminal function identifier part 1205 islarger than that of the terminal temporary identifier part 1202 isassumed and shown.

Using the above procedures, the control procedure shown above can beutilized and following the procedure, control is carried out to enablecommunication with minimized amount of information used for functionswitching.

As mentioned above, it becomes possible to minimize information amountof a flag for each of the communication terminal apparatus 200 used forswitching functions of the communication terminal apparatus 200 bycarrying out communication while corresponding a function and a terminalfunction identifier between the communication control apparatus 100 andthe communication terminal apparatus 200. Especially, in a case where itis assumed that there is deviation in the ability of a communicationterminal apparatus 200 group held by the communication control apparatus100, for example, a case where communication terminal apparatuses 200which is used as a remote sensor and hardly has change in parameter areincluded with a certain ratio, a terminal function identifier spaceprepared for a parameter to enable change of function can be set smallerthan “number of terminals which can be held” x “number of functionswhich can be selected”. Therefore, it becomes possible to reduce theinformation amount than a case where a normal function flag bit row isused.

Here in the present embodiment, a terminal function identifier isallocated by the communication control apparatus 100 upon request fromthe communication terminal apparatus 200 (designated functioninformation). However, allocation of a terminal function identifier maybe carried out taking circumstances of the communication controlapparatus 100 into consideration. For example, in a case of a smallcommunication control apparatus 100 which has limitation in usablefunctions, for example the antennas for MIMO is limited to two, even iffour antennas for MIMO are requested, only two may be allocated.Moreover, same is applied to a case where number of communicationterminal apparatuses 200 held by the communication control apparatus 100becomes large and many functions cannot be allocated to a terminalfunction identifier.

Second Embodiment

In the first embodiment, a terminal function identifier group is usedfor a parameter which is changed at the time of transmission. In asecond embodiment, an example where a reply from a receiver side iscontrolled by a value of a terminal function identifier will beexplained.

In the OFDMA system, it is required to cause each of the communicationterminal apparatuses 200 to transmit CQI to the communication controlapparatus 100 and to allocate sub-channels having good communicationquality to all the communication terminal apparatuses 200 to obtain auser diversity effect. If all the communication terminal apparatuses 200are caused to frequently transmit CQI in all the sub-channels, itbecomes possible to carry out an ideal allocation of sub-channels.However, in this case, a large portion of an uplink bandwidth isconsumed by the transmission of CQI alone.

An efficient number of sub-channels transmitting CQI differs dependingon the communication condition of the communication control apparatus100 or the like. For example: (1) In a case where there are manycommunication terminal apparatuses 200 held by the communication controlapparatus 100, or communication amount to each of the communicationterminal apparatuses 200 is large enough and there is no sub-channelwhich can be allocated other than the currently-used sub-channel, oneCQI is transmitted; (2) In a case where there are certain amount ofunused sub-channels and communication condition is relatively stable,two CQI of a sub-channel, which has the best quality, of all thecurrently-used sub-channels and other sub-channels are transmitted; (3)In a case where condition of a propagation channel changes frequently,CQI of all the sub-channels are transmitted; and (4) In a case where thepropagation channel is not stabilized at all and it is meaningless totransmit CQI, CQI is not transmitted at all. Such operation methods areconceivable as an example.

In this example, the latter two cases are where propagation condition isbad and if a communication terminal apparatus 200 which is not likely tohave bad propagation condition is held, as shown in (3), transmission ofCQI of all the sub-channels does not substantially occur and if all thetransmission methods of CQI are corresponded all the time, useefficiency of information is decreased. That is, if there are manycommunication terminal apparatuses 200 having low moving speed orcommunication terminal apparatuses 200 used in a fixed manner like aremote sensor, unused bits are increased.

Here, it is possible to increase storage efficiency by previouslydetermining a transmission method of CQI having a possibility of use andallocating a terminal function identifier to each of them as shown inthe first embodiment. For example, it is assumed that there are addressspaces from 0 to 2047 for allocating a terminal function identifier andexcluding address spaces for the communication control apparatus 100,broadcast, and multi-cast, address spaces 1 to 1983 are used. Then, itis possible to determine functions to be used on the basis of the valueof the terminal function identifier in such a manner as address spaces 1to 511 transmit one CQI, address spaces 512 to 1535 transmit two CQI,address spaces 1536 to 1791 transmit CQI of all the channels, andaddress spaces 1792 to 1983 does not transmit CQI. Here, although aborder value of an address is fixed, the border value may be changeableby a method of communication between the communication control apparatus100 and the communication terminal apparatus 200 or the like.

Configuration of the communication control apparatus 100 and thecommunication terminal apparatus 200 are the same as those in FIGS. 1 to4 and therefore explanation thereof is omitted here.

Next, a case where a terminal function identifier of the presentembodiment is used and a case where a conventional terminal temporaryidentifier and a flag bit are used are compared. FIG. 13 includes viewsshowing packet configuration for transmission to the communicationterminal apparatus 200 in a conventional method and the presentembodiment. Upper part of FIG. 13 is a view showing an example of packetconfiguration of a conventional method and lower part of FIG. 13 showsan example of packet configuration of the second embodiment.

A header part 1401 includes control information other than a flag bitsuch as an ID for identifying the communication control apparatus 100 ora time stamp. A terminal temporary identifier part 1402 stores aterminal temporary identifier (logical identifier). A flag bit part 1403stores a flag bit. A pay load part 1404 stores communication data mainbody. The terminal temporary identifier part 1402 is a logicalidentifier used by a conventional method and has a one-to-one relationbetween the communication control apparatus 100 where the terminaltemporary identifier part 1402 is stored and the communication terminalapparatus 200.

Moreover, a terminal function identifier part 1405 stores a terminalfunction identifier explained in the present embodiment. The terminaltemporary identifier part 1402 and the flag bit part 1403 are equivalentto the terminal function identifier part 1405. One or a plurality ofterminal function identifiers are allocated to one communicationterminal apparatus 200 and at the same time transmission number of CQIis allocated to each of the terminal function identifiers by theabove-mentioned method. Therefore, the terminal function identifier hasboth an ability to specify a communication terminal apparatus 200 and anability to specify a function to be used when communicating. Size of anaddress space for allocating a terminal function identifier may be thesame as or larger than that used in a conventional method.Conventionally, the number of communication terminal apparatuses 200which can be held by the communication control apparatus 100 isdetermined by the size of the address space for allocating the terminalfunction identifier. However, in the present embodiment, the number ofcommunication terminal apparatuses 200 which can be held by thecommunication control apparatus 100 is determined by the size of theaddress space for allocating the terminal function identifier and anaverage of number of terminal function identifiers allocated to onecommunication terminal apparatus 200. If an average value of the numberof terminal function identifiers allocated to one communication terminalapparatus 200 is small, the address space maybe the same size as alogical identifier space prepared by a conventional method. However, ifan average value of the number of terminal function identifiersallocated to one communication terminal apparatus 200 is large, it isrequired to prepare an address space for allocating a terminal functionidentifier having additional space for the large average value.

Moreover, the second embodiment and the first embodiment can be combinedfor use. For example, in the first embodiment where propagationcondition is bad, it is conceivable that distributed is used. If thereare cases where CQI is returned to all the channel and CQI is notreturned at all, a terminal function identifier used for the case ofreturning CQI to all the channels in the distributed may be allocatedsomewhere between 1536 and 1791 and a terminal function identifier usedfor the case of not returning CQI at all in the distributed may beallocated somewhere between 1792 and 1983. Thus, it becomes possible toselect how to return CQI without newly increasing combinationinformation of a terminal function identifier and functions used for theselection of a function.

Third Embodiment

In the first and second embodiments, an example where use efficiency ofinformation is improved by causing a function to correspond to aterminal function identifier was explained. In a third embodiment, anidentifier including a terminal temporary identifier and a mode numberspecifying a function is used, a function to be used in a condition of acommunication control apparatus is selected, and ratio of the terminaltemporary identifier and the mode number in the information amount ofthe terminal function identifier is adjusted so that use efficiency ofinformation can be improved.

In the present embodiment, a case where a network topology called acommunication control apparatus (control station, base station) and acommunication terminal apparatus (mobile station) is used in the OFDMAsystem is explained. However, the present embodiment can be applied toother network topology.

FIG. 14 is a block diagram showing a configuration example of acommunication control apparatus 300 of the third embodiment. Explanationon the same constituent elements as those in FIG. 1 will be omitted.

A communication control section 301 is in charge of information datathrough a backbone handled by the communication control apparatus 300 orcontrol of each block of the communication control apparatus 300.Specifically, utilizing control data such as CQI data transmitted from acommunication terminal apparatus, it is determined that which data slotis to be allocated to which communication terminal apparatus, and at thesame time, modulation method of each data slot is determined. Selectionbetween distributed and localized is also made here. Moreover, number ofterminal temporary identifiers is determined by allocation condition ofa slot and number of communication terminal apparatuses being held. Acommunication control section 301 notifies the allocation informationand modulation information to the modulation method selecting section103 and notifies the number of terminal temporary identifiers and othercontrol information including communication condition (communicationtraffic condition) to a function selecting section 302 and an identifiergeneration section 303.

The function selecting section 302 selects at least one function as aselection function from a plurality of functions on the basis of aninstruction from the communication control section 301 and generatesselection function information. The selection function becomes afunction which can switch selective items included in the function. Thefunction selecting section 302 selects a selection function from aplurality of functions on the basis of control information notified bythe communication control section 301. Moreover, the function selectingsection 302 determines the number of selection functions to be selectedon the basis of the number of terminal temporary identifiers notified bythe communication control section 301.

The identifier generation section 303 generates a terminal temporaryidentifier and simultaneously a mode number and a function map on thebasis of control information notified by the communication controlsection 301 and selection function information notified by the functionselecting section 302 in response to an instruction from thecommunication control section 301. The mode number is a numberspecifying a plurality of selective items that the selection functionincludes. If there are a plurality of selection functions, a pluralityof mode numbers specifying combinations of a plurality of selectiveitems that each of the plurality of selection functions has aregenerated. The function map is information correlating a plurality ofmode numbers and selective items that the selection function includes.Moreover, the identifier generation section 303 determines a ratio of amemory for allocating a terminal temporary identifier and a mode numberon the basis of at least either the number of communication terminalapparatuses to be connected or requested communication quality, or onthe basis of other control information based on information transmittedby the communication control apparatus (including designated functioninformation, control information) and the like. Regarding this, detailswill be described later by use of FIG. 20.

An identifier selecting section 304 selects one selective item from aplurality of selective items that the selection function has accordingto an instruction from the communication control apparatus 301 andselects a terminal function identifier correlated to the selectedselective item. Specifically, on the basis of terminal ID information (aterminal unique identifier or terminal function identifier) of acommunication terminal apparatus to be a communication target (adestination communication apparatus), modulation method information, ARQcontrol information indicating a type of selected ARQ, or the like, amode number corresponding to a selective item to be used is selectedfrom a plurality of mode numbers and the identifier generation section303 selects (generates) a generated terminal temporary identifier andthe selected mode number as a terminal function identifier.

An identifier allocation section 305 has a function to generatedifferent terminal identifiers corresponding to each of functions used(terminal function identifiers) and to allocate the terminal identifiersto the destination communication apparatus. FIG. 14 shows an example ofa case where the above-mentioned operation is realized by the identifiergeneration section 303 and the identifier selecting section 304.

Here, the function selecting section 302, the identifier generationsection 303, and the identifier selecting section 304 may be executed bythe communication control section 301 and each of the constituentelements may be provided in the communication control section 301 or inother location. Moreover, same can be applied to the identifierallocation section 305.

FIG. 15 is a block diagram showing a configuration example of acommunication terminal apparatus 400 of the present embodiment.Explanation on constituent elements same as those in FIG. 2 will beomitted.

A communication control section 401 is in charge of communicationcontrol in a communication terminal apparatus 400. The communicationcontrol section 401 receives map data including a function map or thelike, which will be explained by use of FIG. 22, from the communicationcontrol apparatus 300. The communication control section 401 analyzes aterminal function identifier notified by the communication controlapparatus 300 on the basis of data such as the function map, acquires aterminal temporary identifier and a function mode, acquires selectiveitems of a function or the like to be used from the function map and thefunction mode, and carries out communication with the communicationcontrol apparatus 300,

Form of an uplink signal transmitted from the communication terminalapparatus 400 to the communication control apparatus 300 can bebasically any form as long as the signal can ensure reliability thatenables to carry out control shown in the present embodiment or ARQcontrol. For example, a method used for PDC or a method used forwireless LAN may be used.

ARQ is carried out by a control signal transmitted from thecommunication terminal apparatus 400 to the data of the transmittedslot. Because the communication terminal apparatus 400 transmitstransmission/non-transmission of data of the slot on the basis of theARQ control signals at the time of transmission, content of each slot istransmitted again by the transmitted signal. In a case wheretransmission fails after trying retransmission for a predeterminedperiod of time, the transmission data is discarded as timeout. Thetimeout period is set by information exchanged when the communicationterminal apparatus 400 makes a connection request and informationexchanged when the ability change is made.

When the soft handover is carried out, the communication control section301 carries out communication with the communication control section 401of the communication terminal apparatus 400 on the soft handover targetside through a backbone and the soft handover is realized bytransmission from both sides after adjusting timing, modulation method,and transmission data to be transmitted from both sides. Whether thissoft handover is carried out or not is set by information exchanged whenthe communication terminal apparatus 400 makes connection with thecommunication control apparatus 300 and information exchanged at thetime of ability change.

In the present embodiment, the frame configuration shown in FIG. 6 isused as well. Explanation on FIG. 6 is the same as that in the firstembodiment and therefore omitted here.

FIG. 16 is a view showing an example of a function controlled by thecommunication controlling apparatus 300 in the present embodiment. Inthe present embodiment, a case where six functions are used is taken asan example, each function is indicated by use of Flags 1 to 6, and eachfunction has a plurality of selective items. In FIG. 16, an examplewhere functions of Flags 3 and 6 have four selective items, a functionof Flag 5 has eight selective items, and functions of other Flags havetwo selective items is shown. In this example, to transfer the selectiveitems (information) of a function to be used, the Flag 3 requires 2-bit,the Flag 5 requires 3-bit, and other Flags require 1-bit flag bit.

Each of the functions shows the following contents. A first functionshown by the Flag 1 indicates whether allocation method of a slot to acommunication terminal apparatus is distributed or localized, A secondfunction shown by the Flag 2 indicates whether soft handover is carriedout or not. A third function shown by the Flag 3 indicates how many MIMOantennas are to be used. A fourth function shown by the Flag 4 indicateswhether ARQ timeout period is set long or short. A fifth function shownby the Flag 5 indicates what type of modulation method is currently usedby the communication control apparatus. A sixth function shown by theFlag 6 indicates bit number of a terminal function identifier currentlyused by the communication control apparatus. An outline of a functionwhich is switched by the Flags 5 and 6 is shown in the following.Moreover, each of the functions is not directly related to the essenceof the present invention and therefore outlines thereof is roughlyshown. The other functions are the same as those explained in the firstembodiment and therefore explanation thereof is omitted here.

A modulation method shows how each of sub-carriers of the OFDM ismodulated and coding rate of an error correction signal. A terminaltemporary identifier is an ID temporarily allocated when a communicationterminal apparatus is connected to a communication control apparatus andis used for reduction of information in a case where a bit-length of aterminal unique identifier uniquely allocated to the communicationterminal apparatus is long. Generally, one terminal function identifieris allocated to one communication terminal apparatus and a few multicastaddresses are allocated at most. Therefore, it is necessary to prepare abit number corresponding to the number of communication terminalapparatuses which can be held by the communication control apparatus.

If all the above-mentioned functions are used and a terminal temporaryidentifier bit number is used at a maximum, a total of a number of aflag bits indicating functions and a number of bits for a terminaltemporary identifier reaches 24 bits. In the present embodiment,functions are indicated by mode numbers generated by the identifiergeneration section 303. Therefore, it can be said that the memory usedfor a terminal function identifier which is a sum of a mode number and aterminal temporary identifier reaches 24 bits. To all the informationtransmitted within the frame, this 24-bit memory for a terminal functionidentifier (also referred to as a “control information memory” or“identifier memory”) is required and therefore, it is better if thecontrol information amount included in the terminal function identifierbecomes smaller. Moreover, because information of this bit number isadded to the all the communication data, it is preferable that thecontrol information becomes smaller from the viewpoint of communicationefficiency. In the present embodiment, information required for theterminal function identifier is efficiently selected according to thecondition of the communication control apparatus 300 and stored in thememory, Specific condition of the communication control apparatus 300will be shown below for an explanation.

First, a condition where all the functions stipulated by specificationof the communication control apparatus 300 can be used and thecommunication terminal apparatuses held by the communication controlapparatus 300 is small enough is assumed. In such a condition, thecommunication control apparatus 300 must allow all the functions to beusable depending on the condition of the communication terminalapparatus 400 and the bit number used for the terminal functionidentifier must be minimized. A condition where use of functions isprioritized is referred to as a function prioritized condition. FIG. 17is a view showing an example of a utilization condition of a memory inthe function prioritized condition. In the function prioritizedcondition shown in FIG. 17, a total bit number used for a terminalfunction identifier which is a sum of a mode number indicating functionselection a terminal temporary identifier reaches 18-bit.

Next, a case where usable functions of the small communication controlapparatus 300 is limited is assumed. Here, it is assumed that usablefunctions are limited to switching of distributed/localized, twoantennas for MIMO, switching long/short of ARQ timeout period, andmodulation methods of QPSK R=1/2, 3/4, 16QAM R=1/2 and 3/4, and a bitnumber to be used as a terminal function identifier is limited to12-bit. Such a condition where a part of functions is limited isreferred to as a function limitation condition. FIG. 18 is a viewshowing an example of a utilization condition of a memory in a functionlimitation condition. In the function limitation condition shown in FIG.18, total bit number used for a terminal function identifier is 18 bits.

Finally, a case where the number of communication terminal apparatuses400 held by the communication control apparatus 300 is temporarilyincreased by commuter rush or the like is assumed. In such a case, it isrequired to increase the number of usable terminal function identifierseven if usable functions are limited in some degree. A condition wherethe number of terminal temporary identifiers is prioritized is referredto as a terminal number prioritized condition. FIG. 19 is a view showingan example of a utilization condition of a memory in a terminal numberprioritized condition. In the terminal number prioritized conditionshown in FIG. 19, total bit number used for a terminal functionidentifier is 18 bits.

Thus, compared to a case where all the functions and all the terminaltemporary identifiers (a maximum number of terminal temporaryidentifiers) are used (24 bits are used), according to the presentembodiment, it becomes possible to require functions with the 6-bit lessbit number.

This is, in other words, ratio of length of a bit of a mode numberindicating a combination of functions and length of a bit of a terminalfunction identifier is changed depending on the condition of thecommunication control apparatus. FIG. 20 is a view showing an example ofutilization ratio of a memory for a terminal function identifier. Theupper part of FIG. 20 is an example of a case of function prioritizedcondition and the lower part of FIG. 20 is an example of a case ofterminal number prioritized condition. As shown in the upper part ofFIG. 20, in a case where the number of functions to be used is increasedto reduce bit number used for the terminal function identifier, ratiofor usage of mode number is increased, while as in the lower part ofFIG. 20, in a case where the number of functions to be used is reducedto increase the bit number used for the terminal function identifier,ratio for the terminal temporary identifier is increased. Here, the modenumber depends on the functions and the terminal temporary identifierdoes not depend on the function. Therefore, an area to which the modenumber is allocated can be referred to as an area relying on thefunction while an area to which the terminal temporary identifier isallocated can be referred to as an area which does not depend on thefunction. Depending on which function is to be used among a plurality offunctions, ratio of an area which depends on the function and an areawhich does not depend on the function is changed for use.

As mentioned above, in the present embodiment, a memory for a terminalfunction identifier which is a combination of a mode number and aterminal temporary identifier can be efficiently used depending on thecondition of the communication control apparatus 300. Moreover, it isalso possible to optimize utilization condition of the memory dependingon the condition of the communication control apparatus 300. Further, itis possible to change usage of the memory depending on the condition ofthe communication control apparatus 300 and therefore it becomespossible to reduce memory amount allocated to a terminal functionidentifier.

Next, an example of allocating a mode number will be explained showing acase of a function limitation condition shown in FIG. 18 as an example.In FIG. 18, a case where usable functions are limited to switching ofdistributed/localized, two antennas for MIMO, switching long/short ofARQ timeout period, and modulation methods of QPSK R=1/2, 3/4, 16QAMR=1/2 and 3/4 is assumed. Numbers of bits required to express a functionused in this function limitation condition are 5 bits: 1 bit forswitching distributed/localized; 1 bit for switching one/two antennasfor MIMO; 1 bit for switching long/short of ARQ timeout period; 2 bitsfor switching four types of modulation methods. Mode numbers areallocated to all these combinations. FIG. 21 is a view showing anexample of allocation of a mode number in the case of functionlimitation condition shown in FIG. 18. In the present embodiment, atable for allocation of mode numbers shown in FIG. 21 is referred to asa function map. The identifier generation section 303 allocates(generates) a mode number specifying selective items of each functionand generates a function map correlating the selective items of eachfunction and mode numbers.

In a case where the number of functions used is changed according to thenumber of communication terminal apparatuses 400 held by thecommunication control apparatus 300, judgment can be made by whether thenumber of terminals exceeded a predetermined threshold value or not. Inorder not to increase the update frequency of the function map, thethreshold value may have hysteresis characteristics with a certainwidth,

Here, a case where the number of functions of the communication controlapparatus 300 is adjusted according to the number of terminals held isexplained. However, the number of terminals held may be adjusted toprioritize the number of functions of the communication controlapparatus 300. A case where communication with high data rate isrequested by the communication control apparatus 300 and a modulationmethod with high multiplicity such as multi-antenna MIMO, 16 QAM, or 64QAM must be used corresponds to this case. In such a case, number offunctions of the communication control apparatus 300 may be increased asmuch as needed and the bit number of the terminal temporary identifiermay be reduced.

Generation of the terminal function identifier shown in FIGS. 17 to 19and generation of the function map shown in FIG. 21 are executed by thefollowing procedure. The function selecting section 302 determines thenumber of functions to be selected by the communication controlapparatus 300 as selection functions and selects selection functionsfrom the plurality of functions on the basis of the condition ofcommunication control apparatus 300 notified by the communicationcontrol section 301. Condition of the communication control apparatus300 includes number of the communication terminal apparatuses 400 to beconnected (number of terminals held), processing ability of thecommunication control apparatus 300, requested communication quality andthe like, as mentioned above. Next, the identifier generation section303 determines ratio of a memory shown in FIG. 20 on the basis of thenumber of selection functions selected by the function selecting section302 and control information including the condition of the communicationcontrol apparatus 300 notified by the communication control section 301.Subsequently, the identifier generation section 303 generates modenumbers specifying selective items of each function on the basis ofterminal temporary identifiers fulfilling the number of terminals heldbeing connected and selection function selected by the functionselecting section 302 and further generates a function map. Here,regarding functions which were not selected by the function selectingsection 302, anyone of selective items that each function has is set tobe a fixed value to cause the functions to be fixed value functions.

Next, a method to notify the function map to a communication terminalapparatus 400 held by the communication control apparatus 300 will beshown, The communication control apparatus 300 notifies the function mapand the fixed value function to the communication terminal apparatuses400, Although the function map and the fixed value function are largeinformation, update frequency thereof is very low. Therefore, thecommunication control apparatus 300 can notify them to each of thecommunication terminal apparatuses 400 even though it takes time.

FIG. 22 is an example of a frame configuration and an example of dataconfiguration of the function map to be notified. As shown in FIG. 22(a), utilizing a part 1003 of a control slot 1001 in a frame 1000 (ashaded area), a plurality of frames are used to notify in the presentembodiment. For example, consecutive 32 frames are assumed to be 1 setand notification of the function map and the fixed value function iscarried out. Hereinafter, the function map and the fixed value functionmay be referred to as “function map and the like”.

Moreover, the function map and the fixed value function used by thecommunication control apparatus 300 and the function map and the fixedvalue function understood by the communication terminal apparatus 400must correspond one to one. If this correspondence does not match,required information cannot be taken on the communication terminalapparatus 400 side. Therefore, the communication terminal apparatus 400notifies in advance before the function map and the like is changedsimultaneously with the transmission of the same information a pluralityof times carried out to prevent failure in reception. The communicationcontrol apparatus 300 uses the currently used function map and the fixedvalue function, a function map and a fixed value function to be usedfrom the next update time, and estimated time of update as shown in FIG.22 (b). Data configuration shown in FIG. 22 (b) is assumed to be mapdata. Moreover, in the control slot 1001, it is assumed that time in thecommunication control apparatus 300 is displayed. As an example, it isassumed that update of the function map and the like is carried out withthe unit of 512 mS, one frame is expressed by 2 mS and the map isexpressed by 32 frames one set, same information can be transmittedeight times within the 512 mS. Further, the communication controlapparatus 300 transmits a Map A which is the function map and the likecurrently used, a Map B to be used after update, and a Time B which isan estimated time of next update at time A as shown in FIG. 22 (c),transmits the Map B which is the function map and the like currentlyused, a Map C to be used after update, and a Time C which is anestimated time of next update at time B as shown in FIG. 22 (d), andtransmits the Map C which is the function map and the like currentlyused, a Map D to be used after update, and a Time C which is anestimated time of next update at time D as shown in FIG. 22 (e).

The communication terminal apparatus 400 causes the current time shownin the control slot 1001 and time inside the communication terminalapparatus 400 to be synchronized and updates the function map and thelike to a new function map and the fixed value function when theestimated time of update comes. In the present embodiment, there areeight receiving opportunities until the function map and the like areupdated and therefore in most cases, the update of the function map andthe like succeeds. If reception cannot be made for a long period oftime, the communication terminal apparatus 400 must stop receivingfollowing data slot 1002 until correct map data is received.

Here, a serial number updated every time the function map is updated maybe added to the function map included in the map data. In this case, itis possible to explicitly show that the content of the function map isnot changed even if the update time indicated in the map data comes. Ifthe serial number is added, there is a disadvantage that information forthe amount of the serial number is increased. However, there is anadvantage that even if the communication terminal apparatus 400 fails toreceive the map data for a period longer than the update period of themap data due to a certain reason, it is immediately understood that thedata has not been changed by checking the serial number and receptionprocessing can be resumed at this point of time.

As explained above, if the communication terminal apparatus 400 findsthe communication control apparatus 300, function map data in a controlslot is received. After confirming the function map data is receivedwithout an error, the communication terminal apparatus 400 startsconnection operation. Subsequently, the communication terminal apparatus400 keeps receiving map data allocated to the part 1003 in the controlslot 1001, checks update time in the map data, and carries out update ofthe function map and the like referred in the communication terminalapparatus 400 at a designated time. Thus, demodulation of the data slot1002 provided after the control slot is enabled. If the function map andthe like can be correctly updated, the communication terminal apparatus400 can carry out normal communication.

Using the above procedures, it becomes possible to carry outcommunication in a condition where information amount for selection of afunction used by the communication control apparatus and designation ofthe communication terminal apparatus can be reduced.

Thus, according to the present embodiment, the identifier generationsection 303 is enabled to generate a mode number in response to thenumber of selection function without corresponding to all of a pluralityof functions and it becomes possible to suppress information amountrequired for adaptive modulation control. Moreover, the identifiergeneration section 303 can flexibly change ratio of the memory allocatedto the terminal temporary identifier and the mode number depending onthe condition of the communication control apparatus 300. Thus,depending on the communication condition, it becomes possible togenerate a terminal function identifier, Therefore, it becomes possibleto optimize the information amount required for the adaptive modulationcontrol. Further, a communication apparatus of the present invention cansuppress information amount as a selection function can be selected froma plurality of functions and ratio of a memory can be changed.

Here in each of the above-mentioned embodiments, the function selectingsection, the identifier generation section, and the identifier selectingsection can be executed by a hardware such as a circuit, by a software,or a combination of a software and a hardware, In a case where thesections are executed by a software, a program is loaded in a memory ina communication apparatus in a calculator and under the control of acentral processing operation apparatus, each of the processing iscarried out. This is a program to realize a communication method whichallocates a terminal identifier to a destination communication apparatusand carries out communication with the destination communicationapparatus by use of a plurality of functions in the communicationapparatus (on the calculator), which executes a step to generatedifferent terminal identifiers corresponding to functions used and toallocate the terminal identifiers to the destination communicationapparatus. A more specific example is a program to realize acommunication method of a communication apparatus which carries outcommunication with a destination by use of a plurality of functionshaving a plurality of selective items in the communication apparatus (onthe calculator) and includes the following steps as an example.

(1) A step to select at least one function from the plurality offunctions as a selection function. (2) A step of generating a pluralityof terminal function identifiers correlating the destinationcommunication apparatus and the plurality of selective items that theselection function has. (3) A step of selecting one selective item fromthe plurality of selective items that the selection function has. (4) Astep of selecting a terminal function identifier correlated with theselected selective item from the plurality of terminal functionidentifiers. (5) A step of transmitting a selected terminal functionidentifier to the destination communication apparatus. Here, any stepother than (1) to (5) may be included and a step of realizing eachprocessing explained in each of the above-mentioned embodiments may befurther included.

Here, configuration of the communication apparatus explained in each ofthe above-mentioned embodiments and each of constituent elements aredetailed means for realization and the present invention is not limitedthereto. Other embodiments can be applied as long as the configurationthereof realizes a function to allocate different terminal identifiersto a destination communication apparatus for the functions used in acommunication apparatus which carries out communication with thedestination allocating the terminal identifiers to a destinationcommunication apparatus and using a plurality of functions. For example,the identifier generation section explained in each of theabove-mentioned embodiments includes a function to allocate a terminalfunction identifier (terminal identifier) to a destination communicationapparatus. The function to allocate the terminal function identifier(terminal identifier) is not limited to the function of the identifierselecting section and may include a part of the function executed by thecommunication control section (e.g., function shown in FIG. 3) orfunction (a part of function) of the identifier generation section 303and the function of the function selecting section 302 shown in FIG. 14.As shown in FIGS. 3 and 14, the identifier allocation section mayinclude a constituent element having functions of the identifiergeneration section and the identifier selecting section.

As mentioned above, according to the embodiment of the presentinvention, it becomes possible to optimize information amount requiredfor adaptive modulation control by use of the terminal functionidentifier explained in each of the above-mentioned embodiments. Thus,it becomes possible to optimize size of a memory for storing informationrequired for the adaptive modulation control. Moreover, since thefunction selecting section selects a selection function from a pluralityof functions, information amount to be notified is reduced. Therefore,it becomes possible to suppress the information amount required for theadaptive modulation control.

What is claimed is:
 1. A wireless terminal apparatus for communicatingwith a base station apparatus with radio communication, the wirelessterminal apparatus comprising: a receiving circuitry for receiving adata packet including control information and communication data; and acontrol circuitry for controlling wireless communication to the basestation apparatus having at least a first identification method and asecond identification method, wherein: the control information includedin the data packet includes a first region to identify a terminalapparatus and a second region to control the wireless communication, asum of an amount of information bits of the first region and an amountof information bits of the second region is constant, the amount ofinformation bits of the first region is one of a first informationamount and a second information amount, the first region is used for oneof a first terminal identifier for the first identification method and asecond terminal identifier for the second identification method, allinformation bits in the first region are used to identify the terminalapparatus, a first communication method uses the first identificationmethod and the first region that has the first information amount, asecond communication method uses the second identification method andthe first region that has the second information amount, the firstinformation amount is greater than the second information amount, andthe control circuitry is further configured to use, based on the firstregion having the second information amount, a part of the second regionthat corresponds to a difference between the first information amountand the second information amount.
 2. The wireless terminal apparatusaccording to claim 1, wherein the control circuitry is furtherconfigured to use, based on the first region having the secondinformation amount, the part of the second region that corresponds tothe difference between the first information amount and the secondinformation amount to control the second communication method.
 3. A basestation apparatus for communicating with a wireless terminal apparatuswith radio communication, the base station apparatus comprising: atransmission circuitry for transmitting a data packet including controlinformation and communication data; and a control circuitry that uses atleast a first identification method and a second identification method,wherein: the control information included in the data packet includes afirst region to identify a terminal apparatus and a second region tocontrol wireless communication, a sum of an amount of information bitsof the first region and an amount of information bits of the secondregion is constant, the amount of information bits of the first regionis one of a first information amount and a second information amount,the first region is used for one of a first terminal identifier for thefirst identification method and a second terminal identifier for thesecond identification method, all information bits in the first regionare used to identify the terminal apparatus, a first communicationmethod uses the first identification method and the first region thathas the first information amount, a second communication method uses thesecond identification method and the first region that has the secondinformation amount, the first information amount is greater than thesecond information amount, and the control circuitry is furtherconfigured to use, based on the first region having the secondinformation amount, a part of the second region that corresponds to adifference between the first information amount and the secondinformation amount.
 4. The base station apparatus according to claim 3,wherein: the control circuitry is further configured to use, based onthe first region having the second information amount, the part of thesecond region that corresponds to the difference between the firstinformation amount and the second information amount to control thesecond communication method.
 5. The base station apparatus according toclaim 4, wherein the base station apparatus is configured to transmit,to the wireless terminal apparatus, information for setting the firstterminal identifier having the first information amount and informationfor setting the second terminal identifier having the second informationamount.
 6. A communication method of a wireless terminal apparatus thatcommunicates to a base station apparatus with radio communication, thecommunication method comprising: receiving a data packet includingcontrol information and communication data; and controlling wirelesscommunication to the base station apparatus using at least a firstidentification method and a second identification method, wherein: thecontrol information included in the data packet includes a first regionto identify a terminal apparatus and a second region to control thewireless communication, a sum of an amount of information bits of thefirst region and an amount of information bits of the second region isconstant, the amount of information bits of the first region is a firstinformation amount or a second information amount, the first region isused for one of a first terminal identifier for the first identificationmethod and a second identifier for the second identification method, allinformation bits in the first region are used to identify the terminalapparatus, a first communication method uses the first identificationmethod and the first region that has the first information amount, asecond communication method uses the second identification method andthe first region that has the second information amount, the firstinformation amount is greater than the second information amount, and apart of the second region that corresponds to a difference between thefirst information amount and the second information amount is used tocontrol the wireless communication to the base station apparatus.
 7. Acommunication method of a base station apparatus that communicates to awireless terminal apparatus with radio communication, the communicationmethod comprising: transmitting a data packet including controlinformation and communication data; assigning a plurality of terminalidentifiers to the wireless terminal apparatus; and controlling wirelesscommunication with the wireless terminal apparatus using at least one ofa first identification method and a second identification method,wherein: the control information included in the data packet includes afirst region to identify a terminal apparatus and a second region tocontrol the wireless communication, a sum of an amount of informationbits of the first region and an amount of information bits of the secondregion is constant, the amount of information bits of the first regionis one of a first information amount and a second information amount,the first region is used for one of a first terminal identifier for thefirst identification method and a second terminal identifier for thesecond identification method, all information bits in the first regionare used to identify the terminal apparatus, a first communicationmethod uses the first identification method and the first region thathas the first information amount, a second communication method uses thesecond identification method and the first region that has the secondinformation amount, the first information amount is greater than thesecond information amount, and a part of the second region thatcorresponds to a difference between the first information amount and thesecond information amount is used to control the wireless communicationto the wireless terminal apparatus.